A belt driving apparatus includes a driving pulley r a driven pulley and an endless toothed belt. Each of the driving pulley and the driven pulley includes an outer circumference surface provided with a plurality of teeth. The toothed belt, wound around the driving pulley and the first driven pulley, includes an inner surface provided with a plurality of teeth arranged to mesh with the teeth of the driving pulley and the first driven pulley. The belt driving apparatus also includes an idler pulley having a belt contact surface coming into contact with the outer surface of the toothed belt. As viewed along the width direction of the belt contact surface, the idler pulley includes a center portion and two end portions sandwiching the center portion. The center portion of the idler pulley is greater in diameter than each of the two end portions.
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1. A transfer robot comprising:
a belt driving apparatus; and
a hand attached to the belt driving apparatus;
the belt driving apparatus includes:
a driving pulley including an outer circumference surface provided with a plurality of teeth;
a first driven pulley including an outer circumference surface provided with a plurality of teeth;
a second driven pulley including an outer circumference surface provided with a plurality of teeth;
an endless toothed belt wound around the driving pulley, the first driven pulley and the second driven pulley, the toothed belt including an inner surface provided with a plurality of teeth meshing with the plurality of teeth of each of the driving pulley, the first driven pulley and the second driven pulley; and
first and second idler pulleys each including a belt contact surface in contact with an outer surface of the toothed belt, each of the first idler pulley and the second idler pulley including, along a width direction of the belt contact surface, a center portion and two end portions sandwiching the center portion,
wherein the first idler pulley and the second idler pulley are arranged to sandwich the driving pulley in a travel direction of the toothed belt,
the plurality of teeth of the toothed belt are inclined with respect to a width direction of the toothed belt,
the plurality of teeth of the driving pulley are inclined with respect to an axis of the driving pulley in a manner corresponding to the plurality of teeth of the toothed belt, and the plurality of teeth of each of the first and the second driven pulleys are inclined with respect to an axis of the respective first and second driven pulleys in a manner corresponding to the plurality of teeth of the toothed belt,
in each of the first and the second idler pulleys, the center portion is greater in diameter than each of the two end portions to maintain the toothed belt at the center of the belt contact surface in a width direction of the belt contact surface, and
the transfer robot further includes an angle adjustment mechanism for adjusting an angle of an axis of the first idler pulley with respect to an axis of the driving pulley.
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3. The transfer robot according to
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13. The transfer robot according to
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1. Field of the Invention
The present invention relates to a belt driving apparatus including a driving pulley, a driven pulley, and an endless toothed belt wound around the pulleys. In particular, the present invention relates to a belt driving apparatus for use in a transfer robot having a belt-driving-type linear transfer mechanism.
2. Description of the Related Art
As a type of robot for transferring workplaces, robots having a mechanism for moving a hand along a linear movement path (linear movement mechanism) are known (see JP-A-2008-272847, for example). Such a transfer robot having a linear movement mechanism has a simple structure and is inexpensive as compared with articulated robots, and hence, is widely used to transfer a wafer, a glass substrate or the like into or out of a chamber in manufacturing a semiconductor device or a liquid crystal panel, for example.
The transfer robot disclosed in JP-A-2008-272847 includes a belt driving apparatus for driving the linear movement mechanism. As shown in
In recent years, the size of a workpiece such as a panel for making a liquid crystal panel is being increased, and hence there is a demand for increasing the movement distance of a hand of a transfer robot for holding a workplace. Moreover, to enhance the productivity, transferring workplaces at high speed and with high accuracy is also demanded. In a transfer robot using the above-described belt driving apparatus, the movement distance of the hand can foe increased relatively easily by increasing the lengths of the output belt and the guide rail for supporting the hand. Further, the transfer speed can also be increased by using toothed pulleys as the driving pulley and driven pulleys and using, as the output belt, a tiding belt (toothed belt) having teeth on the inner surface for meshing with the pulleys. This arrangement prevents slipping between the output belt and the driving pulley or driven pulleys in the travel direction of the belt.
In a belt driving apparatus having an output belt wound around a plurality of pulleys, it is desirable that the rotation axes of the pulleys are set precisely parallel to each other. In practice, however, due to errors in making or mounting each pulley, it is difficult to set the rotation axes of the pulleys parallel to each other with sufficient accuracy. Further, output belts vary from each other. Because of these reasons, when an output belt runs, the output belt may deviate toward one side in the axial direction of the pulley (driving pulley or driven pulley) so that an edge of she output belt may come into contact with a collar portion provided at each end of the pulley in the axial direction. In such a case, the output belt cannot run stably and may break if continues traveling. When the length of the output belt is increased or the travel speed of the belt is increased to realize high-speed transfer of workplaces, the amount of displacement of the output belt in the width direction increases, which increases the possibility that the above-described problem will occur.
The present invention has been proposed under the circumstances described above. It is therefore an object of the present invention to provide a belt driving apparatus capable of preventing deviation during traveling of an endless toothed belt wound around a driving pulley and a driven pulley.
To achieve the above-described object, the present invention takes the following technical means.
According to an embodiment of the present invention, there is provided a belt driving apparatus comprising: a driving pulley including an outer circumference surface provided with a plurality of teeth; a first driven pulley including an outer circumference surface provided with a plurality of teeth; an endless toothed belt wound around the driving pulley and the first driven pulley, the toothed belt including an inner surface provided with a plurality of teeth meshing with the plurality of teeth of each of the driving pulley and the first driven pulley; and a first idler pulley including a bolt contact surface coming into contact with an outer surface of the toothed belt, the first idler pulley including, along a width direction of the belt contact surface, a center portion and two end portions sandwiching the center portion, the center portion being greater in diameter than each of the two end portions.
Preferably, the belt driving apparatus of the present invention may further comprise: a second driven pulley including an outer circumference surface provided with a plurality of teeth; and a second idler pulley including a belt contact surface coming into contact with the outer surface of the toothed belt. The first driven pulley and the second driven pulley define therebetween a straight travel section in which the toothed belt is caused to move along a straight travel path. The first idler pulley and the second idler pulley are arranged to sandwich the driving pulley in a travel direction of the toothed belt.
Preferably, each of the first and the second idler pulleys may have a winding angle indicating a contact region between the belt contact surface of said each of the first and the second idler pulleys and the outer surface of the toothed belt, where the winding angle is not less than 50°, for example.
Preferably, the toothed belt may be provided with a carriage that is moved reciprocally in the straight travel section.
Preferably, the belt driving apparatus of the present invention may further comprise an angle adjustment mechanism for adjusting the angle of the axis of the first idler pulley with respect to the axis of the driving pulley.
Preferably, the belt driving apparatus of the present invention may further comprise an auto tension mechanism including a biasing member for urging the outer surface of the toothed belt via the first idler pulley.
Preferably, in the belt driving apparatus of the present invention, the plurality of teeth of the toothed belt are inclined with respect to a width direction of the toothed belt. Correspondingly, the plurality of teeth of the driving pulley are inclined with respect to an axis of the driving pulley, and the plurality of teeth of the first driven pulley are inclined with respect to an axis of the first driven pulley.
Other features and advantages of the present invention will become clearer from the detailed description given below with reference to the accompanying drawings.
Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.
The rotary base 2 is supported on the stationary base 1 to be movable up and down and refutable about a vertical rotation axis Os. In the stationary bass 1 are provided an elevation motor and a rotation motor (not shown) which drive the rotary base 2 into up-and-down movement and rotational movement. The guide member 3 is shaped like a box that is an elongated rectangle as viewed in plan. The guide member 3 has in it a guide rail (not shown) for supporting the hands 5A and 5B individually. The hands 5A and 5B are slidable along a horizontal and straight movement path GL without interfering with each other while being supported by the guide rail.
As shown in
The belt driving apparatuses 4 are provided for making the hands 5A and 5B to slide on the guide rail. The belt driving apparatuses 4 are provided in a pair correspondingly to the two hands 5A and 5B (see
As shown in
As the material for the output belt 44, vinylidene fluoride-based fluorocarbon robber (FKM) that can be adapted for use in high temperature environment (e.g. about 160° C.) is suitably used. Use may also be made of an output belt 44 of which strength is enhanced by embedding in the main body portion 442 of the output belt 44 a glass core wire as a reinforcing material extending in the belt travel direction. Such on output belt containing a glass core wire does not largely change its length due to tension load or temperature change. For example, the output belt 44 is about 5-10 m in overall length in the travel direction, about 60 mm in width L1, and about 2 mm in thickness T1 of the main body portion 442. The pitch P1 of the teeth 441 is about 8 mm, and the inclination angle α of the teeth 441 with respect to the width direction is about 1*.
As shown in
As shown in
As shown in
As shown in
As shown in
In this embodiment, both of the two idler pulleys 43 are arranged adjacent to the driving pulley 41. As will be understood from
The belt driving apparatus 4 of this embodiment further includes an angle adjustment mechanism 45 (see
The auto tension mechanism 46 is a mechanism for applying tension to the output belt 44 by biasing the outer surface 44a. As shown in
As shown in
The advantages of the belt driving apparatus 4 according to the foregoing embodiment are described below.
The idler pulleys 43 apply tension from the outer side to the output belt 44 that has teeth 441 on the inner surface. As noted before, each idler pulley 43 gradually bulges as proceeding from each end toward the center in the width direction. Thus, the idler pulley 43 applies a larger tension to the output belt 44 at the center in the width direction of the belt contact surface 43a than at other portions. Generally, belts tend to shift toward a higher tension side during its traveling. Thus, as shown in
In the foregoing embodiment, the driving pulley 41 or the driven pulleys 42, which are designed as toothed pulleys, are not configured to gradually bulge toward the center, but the idler pulleys 43 for coming into contact with the flat outer surface 44a of the output belt 44 are configured to gradually bulge toward the center. As compared with the case where the driven pulleys 42 are configured into a bulging shape, configuring the idler pulleys 43 into a bulging shape does not require a complicated working process or the like and does not largely increase the cost for manufacturing the belt driving apparatus 4.
The teeth 441 on the inner surface of the output belt 44 are inclined with respect, to the width direction of the output belt 44, and the mating teeth 411, 421 of the driving pulley 41 and the driven pulleys 42 are inclined with respect to the respective axial directions, correspondingly to the teeth 441. Such inclination of the teeth 441 causes the output belt 44 to deviate toward one side in the width direction during its traveling. During the reciprocal movement of the output belt 44 in the straight movement section 47a, the output belt 44 tends to deviate toward one side in the width direction when moving in one direction and deviate toward the other side in the width direction when moving in the other direction. The action of the idler pulley 43 to correct the position of the output belt 44 to the center in the width direction is more effective when the idler pulley 43 is positioned on the downstream side of the driving pulley 41 in the belt travel direction than when the idler pulley 43 is positioned on the upstream side. In the foregoing embodiment, the idler pulley 43 is provided on each side of the driving pulley 41 in the belt travel direction. This arrangement assures that the output belt 44 does not deviate toward either side in the width direction during the reciprocal movement.
The idler pulleys 43 are provided adjacent to the driving pulley 41, and the outer surface 44a of the output belt 44 is in contact with the belt contact surface 43a of each idler pulley 43 over the winding angle β of not less than 50°. Achieving winding of the output belt 44 over a certain winding angle assures that tension is properly applied to the output belt 44 and the position, of the output belt 44 is properly maintained at the center in the width direction.
As noted before, the belt driving apparatus 4 of the foregoing embodiment includes the angle adjustment mechanism 45 for adjusting the axial direction of the idler pulley 43 relative to the axial direction of the driving pulley 41. Thus, even when a different output belt 43 is used, deviation of the output belt 43 in the width direction during traveling is prevented by appropriately adjusting the axial direction of the idler pulley 43 for that output belt 43.
As described with reference to
Though an embodiment of the present invention has been described above, the technical scope of the present invention is not limited to the foregoing embodiment. The specific structure of each part of the belt driving apparatus according to the present invention can be varied in design in many ways without departing from the spirit of the invention.
In the foregoing embodiment, the idler pulleys 43 each having a bulging shape are arranged adjacent to the driving pulley 41, as described with reference to
Alternatively, as shown in
In the foregoing embodiment described with reference to
In the belt driving apparatus of the foregoing embodiment, the output belt is moved reciprocally so that the carriage (object to be moved) moves reciprocally in accordance with the movement of the output belt. However, the present invention is not limited to this arrangement. For instance, the belt driving apparatus may not include the carriage but may be designed such that the output belt rotates in one direction instead of moving reciprocally.
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